Device for controlled anaesthesia, analgesia and/or sedation

ABSTRACT

A device for inducing anaesthesia, analgesia and/or sedation is described which comprises a container holding an inert gas-containing liquid preparation, and means for the controlled administration of the preparation to a patient.

CROSS REFERENCE TO RELATED APPLICATION(S)

This application is a divisional of application Ser. No. 09/037,793,filed on Mar. 10, 1998, now allowed, and claims priority to GermanPatent Application No. 197 09 704.9, filed Mar. 10, 1997, and EuropeanPatent Application No. 97 113 756.7, filed Aug. 8, 1997.

The invention relates to a device which can be used to control theanaesthesia, analgesia and/or sedation of a patient.

Control is understood here as meaning that a patient's condition(anaesthesia, analgesia and/or sedation) can be changed in the shortestpossible time from the patient's actual condition to a required ordesired condition. This means e.g. that, in the case of anaesthesia, theconditions (1) analgesia, (2) loss of consciousness and (3) muscularrelaxation are reached in the shortest possible time and that thetransition from the anaesthetized condition to full consciousnessproceeds rapidly and without complications. Control also means that,once a condition has been reached, it is kept stable over long periods(hours to days). This means that, even under drastically changingcircumstances, the condition is maintained and subsequent control can beeffected without problems.

If such control is to take place reliably and without complications, theactive substance must first meet certain requirements. For example, onefeature of the active substance must be a rapid onset of action (a fewseconds). On the other hand, however, the action must also wear offrapidly (for example 1-3 minutes; reversibility; all defunctionalizationsymptoms must disappear when anaesthesia has ended). A furtherrequirement is an adequate (for example anaesthesiological) safetymargin. The concentration required to achieve the desired condition (forexample loss of pain sensation and loss of consciousness) should beseveral times lower than that which damages the patient's vitalfunctions. Finally, however, the controllability is also a decisivefactor, i.e. the condition can be deepened, relieved or ended by varyingthe concentration or the infusion rate. In the case of longer-lastingoperations (e.g. operations which take more than 10 seconds), anadditional requirement is that the active substance can be administeredin higher concentrations over a longer period of time without causingappreciable side effects.

Although one of the remarkable features of the intravenous anaestheticsin current use is an immediate onset of action, they regularly exhibit ahost of disadvantages. It should be emphasized that propofol andetomidate, in particular, have no analgesic action and are difficult tocontrol. Other disadvantages of these injectable anaesthetics are sideeffects which are difficult to assess (for example drop in bloodpressure, bradycardia, rigidity, allergic reactions) and in some casesserious contraindications. Finally, total intravenous anaesthesia (TIVA)with propofol also frequently results in protracted waking anddisorientation, especially after longer periods of anaesthesia.

Thus it is seen that the presently known intravenous active substancesdo not meet the requirements.

Active substance combinations according to the state of the art do notrepresent a solution to this problem. In the case of anaesthetics inparticular, it is known that combinations produce pharmacokinetic andpharmacodynamic interactions which very definitely cannot be adequatelycontrolled in the maintenance of the anaesthesia. As a consequence ofthe different pharmacokinetics and pharmacodynamics of the respectiveactive substances at a given moment during the anaesthesia, it is notpossible correctly to adjust the concentration and/or the infusion rate.In other words, where active substance combinations are used in anintravenous preparation, the overall action virtually never correspondsto the sum of the individual actions. Such combination preparationstherefore fail to meet the requirement of controllability.

There is consequently a need for a substance, to be used as a singlesubstance or in combination with other active substances, which meetsthe requirements formulated above.

Very precise control of anaesthesia, especially the maintenance ofanaesthesia, requires that a particular concentration of activesubstance in a patient's blood be unambiguously measurable at any time.In the case of simple and easily comprehensible operating procedures andknown pharmacokinetics, limited control is possible by means ofmultistage infusion regimes, for example with propofol. However, suchregimes are inflexible and are unsuitable especially when the activesubstance has to be administered in a controlled manner under changinganaesthetic and operative circumstances.

Because of the lack of flexibility of manual infusion regimes and thehighly complex mathematical models for the pharmacokinetics of the knownactive substances, computer controlled infusion systems have beendeveloped. These computer systems are programmed with a mathematicalsolution for the pharmacokinetic model of a patient in respect of theactive substance used, for example propofol. The computer thencalculates the infusion rate which is necessary to achieve and maintaina theoretical target blood concentration. This target value isdetermined and adjusted e.g. by an anaesthetist. The computer then alsocontrols the infusion rate at which the active substance is administeredto a patient. This type of control is also known as target controlledinfusion (TCI).

However, there is always uncertainty as regards the concentration of theactive substance because the pharmacokinetics differ from patient topatient. It has in fact been observed that very different targetconcentrations have been determined by anaesthetists in practice. Itfollows from this that there is a considerable need for a system whichcan adjust or control a particular condition during anaesthesia as afunction of a patient's actual requirements during an operation. Thesubstantial differences in the target concentrations of the activesubstance in the blood, and the appreciable variance observed in thecourse of operations with different patients and the drugs additionallyused, lead to the conclusion that TCI does not yet meet the requirementsof effective control in every respect.

Systems are currently under development which make it possible to adjustthe degree of anaesthesia more precisely. These are closed circuitsystems in which the administration of the injectable anaesthetic iscontrolled as a function of the depth of anaesthesia which is actuallymeasured (so-called closed loop anaesthesia systems (CLAN)). However,these systems require a considerable expenditure on equipment in orderprecisely to determine the action of the anaesthetic, i.e. the depth ofthe anaesthesia, in a patient.

In summary, there is therefore not only a need for a substance with ananaesthetic, analgesic and sedative action which meets all therequirements for use in a true control system (TCI or CLAN), aspreviously discussed, but also a need for simpler systems which can alsofunction without complex computer programs and/or expensive measuringinstruments (as well as evaluation programs) and which, in contrast tothe known systems, reflect the true condition (for example trueconcentration in the blood).

The object of the invention consists in providing a device (or facility)which makes it possible to ensure controlled anaesthesia, analgesiaand/or sedation.

This object is achieved by means of a device which is characterized inthat it comprises a container holding a liquid preparation whichcontains a lipophilic inert gas in an amount effective as ananaesthetic, analgesic or sedative, and means for the controlledadministration of the preparation to the patient. The purpose of thisdevice is to administer an inert gas-containing preparation to a patientintravenously or arterially in a time controlled manner. “In a timecontrolled manner” means here that the condition required for example inan operative procedure (anaesthesia, analgesia and/or sedation) canalways be precisely controlled over a given period of time, for example2 minutes or even 1 to 2 hours or more (up to days). This is achievedfor example by aiming for a particular endtidal xenon concentration,which corresponds to the concentration in the blood. In the verysimplest case, the container holding the liquid preparation is asyringe. The means of controlled administration is then the syringeplunger, to which a pressure is applied, for example with the assistanceof a so-called perfuser, said pressure affording a controlledadministration of the preparation (e.g. continuous intravenousadministration of a volume of 20 ml over 30 sec). Such a device makes itpossible to ensure the maintenance of anaesthesia over shorter periodsof time (10 sec to about 60 min). The depth of anaesthesia, theanalgesia, the sedation and/or the muscular relaxation is preciselyadjusted for example via the endtidal xenon concentration. As thepharmacokinetics of the active substance are very much simpler than inthe case of propofol, graded infusion regimes are not necessary.

Another embodiment comprises an infusion bag filled with the liquidpreparation, a tube for connection to the patient, and a simpleregulator for controlling the administration. More complex embodimentscomprise electronic control facilities and pumps, for example infusionpumps.

The required adjustments for the infusion of the liquid preparationcontaining an inert gas can be determined inter alia by simulating thecourse of an operation on a patient beforehand, for example. This meansthat the infusion rate/concentration appropriate for a particularcondition (anaesthesia/analgesia/sedation) is determined on a patientbeforehand. Such a determination can be carried out without problemsimmediately before the actual operation.

The invention is partly based on the surprising discovery that acondition of anaesthesia, analgesia or sedation can easily be controlledwith a liquid preparation containing an inert gas (Kr, Ar, Xe). Xenonhas proved particularly effective in this context.

Xenon is a colourless, odourless and tasteless monoatomic inert gas ofatomic number 54. Xenon is five times denser than air. Naturallyoccurring xenon also contains isotopes, for example the isotopes 124,126, 128, 129, 130, 131, 132, 134 and 136. Synthetic isotopes, likexenon 114, xenon 133 and xenon 142, are known as well. These isotopesdisintegrate with half-lives of between 1.2 seconds and about 40 days.The present invention does not address radioactive xenon isotopes.

Liquid preparations in terms of the present invention are generallypreparations which, by virtue of a certain lipophilicity, can easilytake up a fat-soluble gas like the abovementioned xenon or krypton,examples of said preparations being emulsions.

To achieve a subanaesthetic action, the xenon load in the medicinalpreparation need only be about 0.2 to 0.3 ml of xenon per ml ofemulsion. This means that an analgesic and/or sedative action is assuredfor preparations with a xenon content of at least 0.2 ml/ml emulsion. Ananti-inflammatory action is already observed at 0.1 ml/ml emulsion. Ithas been found that, with continuous infusion over 30 sec, 20 ml of anemulsion containing 0.3 ml of Xe per ml of emulsion produce asubanaesthetic condition in a patient weighing about 85 kg. When workingwith a highly laden perfluorocarbon emulsion containing 2 to 4 ml ofxenon per ml of emulsion, for example, 20 ml of this emulsion areinfused over 30 sec, for example, in order to induce anaesthesia. Aninfusion rate of at least 7.5 ml/min is sufficient to maintain theanaesthesia. A total of 470 ml of emulsion would thus be used for a1-hour operation. With a xenon content of 3 ml of xenon per ml ofemulsion, this corresponds to a xenon volume of 1410 ml, i.e. a fractionof the xenon consumed in inhalation anaesthesia (based on a body weightof 85 kg, this would be a consumption of 16.6 ml per kg in one hour).

It is furthermore possible, and under certain circumstances alsoadvantageous, to include another pharmacologically active agent in thepreparation in addition to the inert gas. This can be an intravenoussedative or anaesthetic, for example. Depending on whether this agent iswater-soluble or fat-soluble, it is then present in the aqueous phase orthe lipid phase together with the xenon. 2,6-Diisopropylphenol, which isan effective anaesthetic (for example 1.5-20 mg/ml), is found to beparticularly suitable for this purpose. Etomidate in concentrations of0.1-2 mg/ml (Hypnomidate®, an imidazole-5-carboxylic acid derivative) isalso suitable. Using dissolved xenon in addition to the otheranaesthetic makes it possible to lower the concentration of e.g.diisopropylphenol or etomidate which is necessary for anaesthetization.Thus, for example, 1 ml of fatty emulsion according to the invention(containing about 0.1 g of fat per ml of emulsion) can contain 2.5-20 mgof 2,6-diisopropylphenol, i.e. for example 2.5, 5.0, 7.5, 10, 15 or 20mg, in addition to the xenon.

In very general terms, the substance with an anaesthetic, analgesic orsedative action which is present together with the xenon can be anotheranaesthetic, an analgesic, a muscle relaxant or a sedative. Examples ofother suitable anaesthetics are barbiturates (barbital, phenobarbital,pentobarbital, secobarbital, hexobarbital and thiopental, inter alia) ingeneral, and opioids. Known analgesics are, inter alia, compounds of themorphine type, e.g. hydromorphone, oxymorphone, codeine, hydrocodone,thebacon, thebaine and heroin. It is also possible to use syntheticderivatives of morphine, e.g. pethidine, levomethadone, dextromoramide,pentazocine, fentanyl and alfentanil. It is also possible to use lesspotent analgesics such as anthranilic acid derivatives (flufenamic acid,mefenamic acid), acrylic acid derivatives (diclofenac, tolmetin,zomepirac), arylpropionic acid derivatives (ibuprofen, naproxen,phenoprofen, ketoprofen) and indoleacetic or indenacetic acidderivatives (indometacin, sulindac). The muscle relaxants used can becentral muscle relaxants, for example baclofen, carisoprodol,chlordiazepoxide, chlormezanone, chloroxazone, dantrolene, diazepam,phenyramidol, meprobamate, phenprobamate and orphenadrine. Sedativeswhich can be used according to the invention are, inter alia,benzodiazepine derivatives such as triazolam, lormetazeban, clotiazepam,flurazepam, nitrazepam and flunitrazepam.

Liguids which can take up lipophilic inert gases are e.g. bloodsubstitutes, including perfluorocarbon emulsions (e.g. Perflubron).

It is generally known that a large number of gases have a highsolubility in perfluorocarbon compounds. A perfluorocarbon emulsionconsists for example of up to 90% (weight/volume) of perflubron (C₈F₁₇)Emulsifiers, for example phospholipids from chicken egg yolk, areadditionally required. These emulsions which can be loaded according tothe invention with xenon have been reported for example by J. A. Wahr etal. in Anesth. Analg. 1996, 82, 103-7.

Suitable fluorocarbon emulsions preferably comprise 20% w/v to 125% w/vof a highly fluorinated hydrocarbon compound, for examplepolyfluorinated bisalkylethenes, cyclic fluorocarbon compounds likefluorodecalin or perfluorodecalin, fluorinated adamantane, orperfluorinated amines like fluorinated tripropylamine and fluorinatedtributylamine. It is also possible to use monobrominatedperfluorocarbons, for example 1-bromoheptadecafluorooctane (C₈F₁₇Br),1-bromopentadecafluoroheptane (C₇F₁₅Br) and 1-bromotridecafluorohexane(C₆F₁₃Br). Other compounds can also be used, includingperfluoroalkylated ethers or polyethers, e.g.(CF₃)₂CFO(CF₂CF₂)₂OCF(CF₃)₂, (CF₃)₂CFO(CF₂CF₂)₃OCF₂(CF₃),(CF₃)₂CFO(CF₂CF₂)₂F, (CF₃)₂CFO(CF₂)₃F and (C₆F₁₃)₂O.

Chlorinated derivatives of the abovementioned perfluorocarbons can alsobe used.

The loading capacity of the abovementioned perfluorocarbon preparationis considerable. Xenon loads of e.g. 1 to 10 ml/ml have been achieved bythe simplest means. For example, these preparations can be loaded withinert gas simply by having the gas passed through them.

It is also possible to use fatty emulsions containing the lipophilicinert gas dissolved or dispersed in the lipid phase.

It has been found that xenon can be added to a fatty emulsion inappreciable amounts. Thus, even by the simplest means, xenon can bedissolved or dispersed in concentrations of 0.2 to 10 ml or more per mlof fatty emulsion (concentrations relate to standard conditions, i.e.20° C. and normal pressure). The xenon concentration depends on a largenumber of factors, especially the concentration of the fat. As a rulethe preparations will be “loaded” with xenon up to the saturation limit.However, it is also possible for very small concentrations to bepresent, provided, for example, that a pharmacological activity canstill be observed on intravenous administration. In the case of a 10%fatty emulsion, it is easily possible to reach xenon concentrations of0.3 to 2 ml of xenon per ml of fatty emulsion. It is of course alsopossible to reach higher values, e.g. 3, 4, 5, 6 or 7 ml of xenon per mlof fatty emulsion. These fatty emulsions are sufficiently stable, atleast in gas-tight containers, for the xenon not to be released as a gasover conventional storage periods.

The lipid phase of the preparation, which takes up the gas, i.e. whichcan dissolve and/or disperse the. gas, is formed mainly of so-calledfats, said fats being essentially esters of long-chain and medium-chainfatty acids. Such fatty acids, saturated or unsaturated, contain 8 to 20carbon atoms. However, it is also possible to use omega-3 or omega-6fatty acids, which can contain up to 30 carbon atoms. Suitableesterified fatty acids are especially plant oils, e.g. cottonseed oil,soya bean oil and thistle oil, fish oil and the like. The majorconstituent of these naturally occurring oils are fatty acidtriglycerides. Preparations in the form of so-called oil-in-wateremulsions are of particular importance, the proportion of fat in theemulsion conventionally being 5 to 30% by weight, preferably 10 to 20%by weight. As a rule, however, an emulsifier is present together withthe fat, proven emulsifiers being soya phosphatides, gelatin or eggphosphatide. Such emulsions can be prepared by emulsifying thewater-immiscible oil with water in the presence of the emulsifier, whichis normally a surface-active agent. Other polar solvents can also bepresent with the water, examples being ethanol and glycerol (propyleneglycol, hexylene glycol, polyethylene glycol, glycol monoethers, awater-miscible ester, etc.). The inert gas can already have beenincorporated into the lipid phase in a previous process step. In thesimplest case,. however, the prepared emulsion is loaded with the xenon.This can take place at various temperatures, for example at temperaturesfrom 1° C. to room temperature. It is occasionally useful here to applya pressure, for example of up to 8 atmospheres or more, to the vesselcontaining the emulsion.

According to the invention, it is possible to use fatty emulsions suchas those employed in intravenous feeding. These fatty emulsions consistessentially of a suitable fatty base (soya bean oil or sunflower seedoil) and a well-tolerated emulsifier (phosphatides). Fatty emulsions ingeneral use are Intralipid®, Intrafat®, Lipofundin®S and Liposyn®. Moredetailed information on these fatty emulsions can be found in G.Kleinberger and H. Pamperl, Infusionstherapie, 108-117 (1983) 3. Thefatty emulsions generally also contain additives which make theosmolarity of the aqueous phase, surrounding the fatty phase present inthe form of liposomes, isotonic with the blood. Glycerol and/or xylitolcan be used for this purpose. Furthermore, it is frequently useful toadd an antioxidant to the fatty emulsion in order to prevent oxidationof the unsaturated fatty acids. Vitamin E (DL-tocopherol), inparticular, is suitable for this purpose.

So-called liposomes, which can be formed from the abovementionedtriglycerides but also generally from so-called phospholipid molecules,are particularly advantageous as the lipid phase, especially in the caseof an oil-in-water emulsion. These phospholipid molecules generallyconsist of a water-soluble part, which is formed of at least onephosphate group, and a lipid part, which is derived from a fatty acid orfatty acid ester.

U.S. Pat. No. 5,334,381 illustrates in detail how liposomes can beloaded with gas. In very general terms, a device is filled with theliposomes, i.e. with an oil-in-water emulsion, and the device is thenpressurized with the gas inside. The temperature can be reduced to aslow as 1° C. in this process. The gas gradually dissolves under pressureand passes into the liposomes. Small gas bubbles may then form when thepressure is released, but these are now encapsulated by the liposomes.It is thus possible in practice to keep xenon gas or other gases, forexample, in a fatty emulsion under hyperbaric conditions. Suchpreparations can also be used according to the invention, provided thata separate gas phase does not form outside the liposomes and oncondition that the desired pharmacological action takes place.

The lipids which form the liposomes can be of natural or syntheticorigin. Examples of such materials are cholesterol, phosphatidylcholine,phosphatidylethanolamine, phosphatidylserine, phosphatidylglycerol,phosphatidylinositol, sphingomyelin, glycosphingolipids, glucolipids,glycolipids, etc. The surface of the liposomes can moreover be modifiedby a polymer, for example by polyethylene glycol.

It is self-evident that the control device according to the inventioncan also include the determination of other experimental values on apatient (for example acoustically induced potentials etc.) in order tobe able to monitor the desired controlled condition more precisely. Asinert gases are only eliminated through ventilation via the lung,however, this is the first time that it has been possible, in theintravenous administration of the inert gas-containing preparation,continuously to determine the actual concentration of an intravenousdrug by measurement of the endtidal concentration of the inert gas(particularly xenon). Therefore both the depth of anaesthesia and thedepth of analgesia, as well as the muscular relaxation, if desired, canbe precisely controlled by controlling various true arterialconcentrations. The invention thus affords real target controlledanaesthesia. No mathematical models for the effective plasmaconcentration are necessary in this case.

As elimination takes place exclusively via the lung, precise control ofthe anaesthesia is even possible in patients with a restricted organicfunction, for example a liver and/or kidney dysfunction.

The invention also provides a device for controlling anaesthesia, theintravenous supply of the inert gas-containing infusion solution beingadjusted as a function of the inert gas concentration in the air exhaledby the patient.

The inert gas concentration in the exhaled air can be measuredparticularly easily, especially in the case of xenon, with a gasdetector.

A characteristic feature of this device is that it is particularlysimple in equipment terms. It can be used especially in emergencymedicine, where facilities with a small space requirement areparticularly advantageous.

This device can also be part of a unit used for monitoring/controllinganaesthesia with a gaseous anaesthetic.

The invention also provides a device for inducing sedation, especiallyanalgesia/sedation, with (a) a facility which provides an emulsioncontaining a lipophilic inert gas in an amount active as a sedative, (b)a means of measuring data, which records a patient's data, said dataallowing a conclusion to be drawn about the patient's condition, and (c)a control means which controls the administration of the emulsion fromthe facility to the patient as a function of the measured data. A devicefor (monitored) analgesia/sedation can be useful especially in thecontext of intensive care and after heart operations. This devicecomprises a perfuser, optionally a means of measuring the exhaled xenon,and a pulsoximeter. It is advantageous that analgesia can be achieved atthe same time as sedation.

In summary, the device according to the invention can be used in avariety of circumstances, especially in intensive care, endoscopy,cystoscopy, superficial interventions and heart operations.

The invention also provides a device for controlled anaesthesia, theconcentration of the xenon in a preparation administered intravenouslyto a patient being regulated as a function of the xenon concentration inthe air exhaled by an anaesthetized patient. Such a device optionallyhas a mixer in which the preparation is mixed with the xenon. This mixercan be temperature controlled (range from 1° C. to 35° C.). (Thepreparation can also have been loaded with xenon beforehand.) As alreadydescribed previously, the xenon dissolves substantially in this process.In the simplest case, the mixer can consist of a vessel through whichthe preparation is passed and which is partially surrounded by asemipermeable membrane permeable to xenon. The concentration of thexenon in the preparation is then essentially determined by the xenonpressure on the semipermeable membrane. Other auxiliary means, forexample active or passive stirrer elements, can additionally beconsidered here in order to improve the dissolution and/or dispersion ofthe xenon gas. The dissolution or dispersion of the xenon can also beimproved by ultrasonic irradiation. By simple observation of thepatient, it is now possible easily to determine, during fullanaesthesia, that xenon concentration in the exhaled air at which theanaesthesia is still adequate. If the depth of anaesthesia is below theadequate level, the latter can be attained by increasing theadministration of xenon by means of the preparation. The supply of xenonvia the preparation can now be controlled by the xenon load and theinfusion rate (e.g. by means of conventional infusion pumps). Thisprocedure virtually allows fine control of the anaesthesia, which couldnot be achieved hitherto with intravenous anaesthetics.

The invention also provides a device which substantially corresponds tothe device described above except that there is no provision for theadmixing of xenon. In such a case, the preparation is always alreadyloaded with xenon and the anaesthesia is controlled by adjusting theinfusion rate or the concentration of the xenon as a function of themeasured expiratory xenon concentration. The concentration of xenon inthe preparation can be reduced for example by admixing anotherpreparation which does not contain inert gas. Here again, simpleinfusion pumps (optionally peristaltic pumps) serve the purposeaccording to the invention. Provision can be made for temperaturecontrol both in this device and in the previously described device wherexenon is mixed into the preparation.

FIG. 1 shows a syringe such as that which can be used in principleaccording to the invention. In this very simple embodiment of theinvention, the syringe, which holds a xenon-containing preparation, canbe thought of as a facility providing a preparation which contains alipophilic inert gas in an amount effective as an anaesthetic, analgesicor sedative.

FIG. 2 shows a device according to the invention which is a filledinfusion bag with a regulator.

FIG. 3 shows a device according to the invention which has a filledinfusion bag with a discharge tube, and a simple regulator forcontrolling the administration.

FIG. 4 shows another device according to the invention.

FIG. 5 diagrammatically shows a device according to the invention forinducing sedation (so-called closed loop arrangement).

FIG. 6 shows a device according to the invention which is part of adevice for carrying out anaesthesia with a gas, and which includes ameans of measuring the inert gas in the exhaled air.

The device according to the invention for carrying out controlledanaesthesia is illustrated in greater detail with the aid of the diagramin FIG. 3.

This device comprises a storage container 30 for a liquid preparationcapable of taking up an inert gas in dissolved form, a gas container 4for the inert gas, and a mixer 3, in which the preparation is mixed withthe inert gas. Control devices (infusion pumps, regulator etc.), withwhich the intravenous administration to the patient is controlled, arenot shown.

A device according to the invention is also illustrated in greaterdetail with the aid of the diagram in FIG. 4. This device can be usedfor controlled anaesthesia, the xenon concentration in the air exhaledby an anaesthetized patient being measured by analysis and the xenonconcentration in a preparation administered intravenously to the patientbeing adjusted as a function of this analytical value. The devicetherefore comprises an optionally temperature-controllable storagecontainer 1 (temperature range 1° C. to 35° C.) for the preparation,which is connected via a line 5 to a mixer 3, again optionallytemperature-controllable. The xenon, which passes from a xenon bottle 4into the mixer 3 via the line 6, the metering unit 2 and another line 7,is mixed with the preparation in the mixer 3, the bulk of the xenondissolving in the emulsion. The xenon-containing preparation then passesvia the line 8 and a venous access into a patient to be anaesthetized.The preparation is conveyed by means of pumps known per se (not shown).In the medical sector, so-called peristaltic pumps are used in thesimplest case here. In the device according to the invention, such pumpscan be provided for example in the line 5 and additionally in the line8. The means of endexpiratoric gas sensory analysis, and the samplingmeans, are not shown. Conventionally the exhaled gas is sampled at thetube attachment or in the region of the mouth in the case of maskrespiration or mask oxygenation during the patient's inhalation andexhalation. Methods of determining the xenon concentration in theexhaled air are generally known (gas detectors and the like).

(Various valves capable of regulating the inflow and outflow ofsolutions and gases are also not shown.)

FIG. 5 diagrammatically shows a device according to the invention withclosed loop control for inducing sedation. Here, on the one hand, theeffective xenon concentration in the blood is measured by measuring theinert gas in the exhaled air. On the other hand, other experimental data(for example acoustically induced potentials) are recorded on thepatient. Both experimental results are used for controlling theperfusion pump.

The data pertaining to the xenon concentration in the exhaled air (xenonsensor/detector 9) and the acoustically induced potentials (recorder10), recorded on a patient 20, are fed to the perfusion pump 21 via thedata lines 22 and 23. The experimental data are processed (for exampleby means of a computer) and converted to the required infusion rate atwhich the xenon-containing preparation enters the patient via the line8. In other words, the measured experimental data control the perfusionpump 21, which in turn determines the infusion rate. The deviceillustrated here is of course only a diagram and an actual devicecomprises indicators and regulators etc., as conventionally provided,for example in order also to allow manual intervention in the control.The supply line to the perfusion pump, and a storage container providinga xenon-laden preparation, are not shown.

FIG. 6 diagrammatically shows how a device according to the inventioncan be incorporated into the general control of anaesthesia. This devicecomprises a storage container 1 for the preparation, the mixer 3, axenon bottle 4 and a metering unit 2. The metering unit 2 is linked to axenon detector 9, which measures the xenon concentration in the air atthe end of exhalation and feeds an experimental value to the meteringunit 2. The metering of the xenon into the liquid preparation is thencontrolled by the metering unit 2. The xenon-containing preparation thenpasses from the mixer 3 through the infusion tube 8 into the patient.The infusion rate can of course also be controlled via the xenonconcentration in the exhaled air.

A control device 40 is also provided for supplying a gaseous orinhalation anaesthetic. This device comprises inlet and outlet tubes 31and 32 for supplying and withdrawing the anaesthetic gas via theinhaling mask 35.

Experimental Section

Fatty Emulsions

The commercially available Intralipid preparations (obtainable fromPharmacia & Upjohn GmbH, Erlangen) were used as fatty emulsions in thefollowing Examples. These emulsions consist essentially of soya beanoil, 3-sn-phosphatidylcholine (from chicken egg yolk) and glycerol. AnIntralipid®10 fatty emulsion, for example, has the followingcomposition:

Soya bean oil 100 g (3-sn-Phosphatidyl)choline from 6 g chicken egg yolkGlycerol 22.0 g Water for injections ad 1000 ml

Adjusted to pH 8.0 with sodium hydroxide.

Energy value/1: 4600 kJ (1100 kcal)

Osmolarity: 260 mOsm/l

An Intralipid®20 fatty emulsion, for example, has the followingcomposition:

Soya bean oil 200 g (3-sn-Phosphatidyl)choline from 12 g chicken eggyolk Glycerol 22.0 g Water for injections ad 1000 ml

Adjusted to pH 8.0 with sodium hydroxide.

Energy value/l: 8400 kJ (2000 kcal)

Osmolarity: 270 mOsm/l

Loading of Perfluorocarbon Emulsion with Xenon

A series of perfluorocarbon emulsions were prepared or purchased andloaded with xenon. The activity of the preparations was verified on ananimal model (rabbit). All the emulsions were used in the same way asthe Intralipid preparations described above, i.e. the experimentalanimal was quickly anaesthetized by an injection in the ear (about 1ml).

Each of the emulsions was placed in a beaker and loaded by having thexenon gas passed through it.

The following perfluorocarbon compounds were used: perfluorohexyloctane(1), perfluorodecalin (2), perflubron (C₈F₁₇) (3).

Emulsifiers, for example egg yolk lecithin (Lipoid E100 from LipoidGmbH, Ludwigshafen), Pluronic PE6800 and Pluronic F68, were also used toprepare the emulsions.

It was established with all the emulsions that a perfluorocarbonemulsion of only 40% (weight/volume, i.e. weight of perfluorocarboncompound to volume of emulsion) could take up 1 to 4 ml of xenon per mlof emulsion.

Experimental Animal Studies

To demonstrate that it is possible according to the invention to controlanaesthesia, in this case maintain anaesthesia, an experiment wasperformed on 24 pigs aged 14 to 16 weeks and weighing 36.4-43.6 kg. Theywere randomly divided into a total of 3 groups, which wereanaesthetized. In all the groups the anaesthesia was inducedintravenously with a bolus injection of pentobarbitone (8 mg/kg bodyweight) and buprenorphine (0.01 mg/kg body weight). In one group(comparative group) the anaesthesia was maintained by the intravenousadministration of 2,6-diisopropylphenol (10 mg/1 ml emulsion). Formaintenance of the anaesthesia, two groups of pigs (according to theinvention), each containing four individuals, received an intravenousinfusion of 1 ml/kg/h of a 10% by weight fatty emulsion according to theinvention which had previously been saturated with xenon (about 0.3 mlof xenon per ml of emulsion). In group 2, 7.5 mg/kg body weight/h of2,6-diisopropylphenol were additionally administered with the fattyemulsion.

The pigs underwent a surgical intervention (standard intervention:section of the left femoral artery) (identical in each group and foreach experimental animal) and the adrenaline level, heart rate, arterialblood pressure and oxygen consumption were recorded. It was alsoestablished how much additional pentobarbitone needed to be administeredin order to bring the analgesia and depth of anaesthesia to the requiredlevel in each group.

TABLE Arterial Adrenaline Heart blood Pentobar- pg/ml rate pressure VO₂bitone Group requirement [min⁻¹] [mm Hg] [ml/min] mg/kg/min Comparative60 115 110 410 0.25 group 134 120 105 391 0.36 112 105 115 427 0.31 8598 101 386 0.42 Group 1 38 112 112 341 0.09 21 106 100 367 0.04 16 95104 348 0.11 30 112 118 334 0.15 Group 2 10 88 100 325 — 23 100 85 346 —14 94 93 331 — 8 104 87 354 —

The values indicated in the Table show that the xenon-containingpreparation is superior to all the currently available intravenousanaesthetics, especially on account of the additional analgesic potency.Thus the pigs in group 1 (10% by weight fatty emulsion saturated withxenon) show, by comparison (cf. comparative group), markedly less stress(adrenaline level), a lower oxygen requirement ({dot over (V)}O₂) and alower pentobarbitone requirement (i.e. better anesthesia). Thedifference relative to intravenous anaesthetics according to the stateof the art is even more clearly apparent when the results in group 2(10% fatty emulsion with 2,6-diisopropylphenol and enriched with xenon)are compared with the comparative group. This shows not only markedlyreduced stress (adrenaline level). With a markedly reduced heart rateand lower arterial blood pressure, coupled with a lower oxygenrequirement, it was possible to dispense with the admistration ofadditional amounts of pentobarbitone.

this study shows that the desired aim, in this case to maintain theanaesthesia, can be achieved over the whole course of the anaesthesia.

The use of perfluorocarbon preparations was studied on another group (4pigs of 31.4 to 39.8 kg body weight). A 40% perfluorocarbon emulsionwith a xenon content of 2.1 ml of xenon per ml of emulsion was used onthis experiment group. For induction and intubation, the pigs received20 ml of the emulsion intravenously over 20 sec (corresponding to 1.34ml xenon/kg body weight). After incubation and respiration, xenon wascontinuously infused intravenously over 30 min, the experimental animalsthereby receiving a total of 75 ml of emulsion (corresponding to 10 mlxenon kg⁻¹h⁻¹).

Arterial Adrenaline Heart rate blood pressure [pg/ml] [min⁻¹] [mm Hg]VO₂ [ml/min] 8 90 101 301 6 87 96 320 10 94 98 308 5 100 106 316

The above Table indicates the experimental results for the adrenalinelevel, the heart rate, the arterial blood pressure and the oxygenconsumption. The results show that, by increasing the xenon load andinfusion rates (over 5 ml/kg/h), complete anaesthesia can be effectedusing only the means according to the invention. Overall, it is evenestablished that the oxyen requirement ({dot over (V)}₂) is lower andthe anaesthesia (adrenaline level and heart rate) is less stressed.

What is claimed is:
 1. Device for carrying out controlled anaesthesia,wherein the intravenous supply of an infusion solution containing alipophilic inert gas is adjusted as a function of the inert gasconcentration in the air exhaled by a patient, comprising a containerfor the infusion solution holding said solution which contains saidlipophilic inert gas and a metering means for controlling the infusionrate.
 2. Device according to claim 1 wherein a patient's experimentaldata are additionally recorded, allowing a conclusion to be drawn aboutthe patient's depth of anaesthesia.
 3. Device for controlledanaesthesia, analgesia and/or sedation, characterized in that the devicecomprises a container holding a liquid preparation which contains alipophilic inert gas in an amount effective as an anaesthetic, analgesicor sedative, and means for the controlled administration of thepreparation to a patient, wherein provision is made for a storagecontainer for a liquid preparation which can take up an inert gas indissolved form, a gas container for the inert gas, and a metering meansfor feeding inert gas into the mixer, in which the liquid preparation ismixed with the inert gas.
 4. Device for inducing sedation, characterizedin that the device comprises (a) a facility which provides a liquidpreparation containing a lipophilic gas in an amount active as asedative, (b) a means of measuring data, which records a patient's data,said data allowing a conclusion to be drawn about the patient'scondition, and (c) a control means which controls the administration ofthe emulsion from the facility to the patient as a function of themeasured data.